Proteomics to predict relapse in patients with myelodysplastic neoplasms undergoing allogeneic hematopoietic cell transplantation

Disease relapse remains a major barrier to success after allogeneic hematopoietic cell transplantation (allo-HCT) in myelodysplastic neoplasms (MDS). While certain high risk genomic alterations are associated with increased risk of relapse, there is a lack of clinically applicable tools to analyze the downstream cellular events that are associated with relapse. We hypothesized that unique proteomic signatures in MDS patients undergoing allo-HCT could serve as a tool to understand this aspect and predict relapse. Using the Center for International Blood and Marrow Transplant Research (CIBMTR) database, we identified 52 MDS patients who underwent allo-HCT and analyzed their proteomic profile from pretransplant blood samples in a matched case-control design. Twenty-six patients without disease relapse after allo-HCT (controls) were matched with 26 patients who experienced relapse (cases). Proteomics assessment was conducted using the Slow Off-rate Modified Aptamers (SOMAmer) based assay. In gene set enrichment analysis, we noted that expression in the hallmark complement, and hallmark allograft rejection pathways were statistically enriched among patients who had disease relapse post-transplant. In addition, correlation analyses showed that methylation array probes in cis- and transcription regulatory elements of immune pathway genes were modulated and differentially sensitize the immune response. These findings suggest that proteomic analysis could serve as a novel tool for prediction of relapse after allo-HCT in MDS. Supplementary Information The online version contains supplementary material available at 10.1186/s40364-023-00550-0.


To the editor
Myelodysplastic neoplasms (MDS) are clonal hematopoietic disorders characterized by ineffective hematopoiesis and risk of transformation to acute myeloid leukemia.While allogeneic hematopoietic stem cell transplantation (allo-HCT) remains a potentially curative treatment, their long-term outcomes are suboptimal [1].Disease relapse remains a major barrier and novel tools to predict relapse are urgently needed.Genomic abnormalities seen in MDS could translate into qualitative and quantitative alterations in downstream protein expression that may influence relapse [2,3].Utilization of proteomics could complement the insights gained through genomics and Biomarker Research † Guru Subramanian Guru Murthy and Tao Zhang are co-first authors and contributed equally to this work.
pave the way for an integrated multi-omics model to better understand relapse.Hence, we conducted a study to analyze the association between proteomics and relapse in MDS patients undergoing allo-HCT.
Using Center for International Blood and Marrow Transplant Research (CIBMTR) database, a retrospective matched case-control study was conducted in MDS patients who underwent allo-HCT from 2009 to 2014.Among 52 patients identified, 26 without relapse after allo-HCT (controls) were matched for 26 with relapse after allo-HCT (cases), based on age, gender, race/ethnicity, performance status, MDS therapy, IPSS-R, donor type, conditioning intensity, and transplant year (Figure S1, Supplement).Only patients with wild-type TP53, RAS pathway, and JAK2 genes were included to promote the discovery of novel risk factors.Relapse was defined as evidence of detectable MDS after allo-HCT, as reported by individual centers.Proteomic profiling was conducted with pre-transplant whole blood samples using Slow Offrate Modified Aptamers (SOMAmer) based assay (details in Supplement) [4].Pathway level differential expression analysis was conducted using gene set enrichment analysis (GSEA) [5].DNA methylation signature in whole blood was investigated using Infinium Methylation-EPIC array (Illumina).A predictive model with multiomics was also constructed using iOmicsPASS approach (details in Supplement).
Baseline characteristics are included in Table S1 (Supplementary Material 1).In proteomic analysis, underexpression or overexpression of several pathway level proteins were seen in patients with or without relapse (Fig. 1).At a single protein level, a statistically significant candidate was not identified after adjusting for variables.However, GSEA showed that hallmark complement (P = 0.024, FDR = 0.036) and hallmark allograft rejection (P = 0.033, FDR = 0.038) pathways were significantly associated with relapse after investigation of several pathways included in GSEA (Supplementary Material 2).Of note, hallmark complement pathway includes a set of genes which encodes the complement system and hallmark allograft pathway includes genes upregulated during graft rejection [6].Immune proteins such as OLR1, S100A12, GP1BA, XPNPEP1, FLY, LYN from hallmark complement pathway, and CRTAM, UBE2N, STAT1, CAPG, FGR, CSK, LYN from hallmark allograft rejection pathway were significantly upregulated in patients with relapse.
For correlation between proteomics and methylation, we found that methylation of probes on cis-regulatory elements in a subset of immune pathway genes were correlated with protein expression that could differentially sensitize the underlying immune response.Methylation in one of two TSS (transcription starting site) probes and four of nine gene-body probes in OLR1 gene region were highly correlated to OLR1 protein expression, while methylation in one of four TSS probes in S100A12 gene and two of eleven gene-body probes in CRTAM gene were highly correlated to their own protein expression (Table S2, Supplement).The methylation levels of transcription factors were also noted to be correlated, such as methylation of the TF (transcription factor) gene PRMD16 and multiple immune-related proteins, including FYN, LYN and GP1BA (Table S3, Supplement).In iOmicsPASS analysis integrating a multi-omics approach, multiple subnetwork edges from TP53 and AKT pathways were enriched in patients with relapse.Most enriched subnetwork edges came from the proteomic data, indicating that proteomic signals might be the main contributor for relapse prediction.However, smaller sample size limits the overall accuracy of this model (60% with 5-fold cross-validation) (Figure S2, Supplement).
While limited studies have evaluated the role of proteomics in MDS, ours is the first to examine its association with relapse after allo-HCT and no prior studies have investigated GSEA pathways in MDS to our knowledge [7,8].Our observation noting an association between relapse with hallmark complement and hallmark allograft rejection pathways and methylation changes in several genes including PRMD16 highlight their potential role in regulating immune dysfunction in relapse [9,10].Given smaller sample size, further validation in an independent large cohort would be needed as our study serves to generate hypothesis and proof of concept.

Fig. 1
Fig. 1 Allograft rejection and complement pathways were enriched in MDS relapse group by proteomics gene set enrichment analysis.A Protein expression heatmap for two representative pathways: complement pathway and allograft rejection pathway; Differentially expressed proteins between nonrelapse and relapse groups are highlighted by red color.B The profile of ES score and positions of DE gene candidates in the rank list from GSEA leading edge analysis.C the normal p value and FDR q value for complement and allograft rejection pathways